ARC BENCHMARKING EQUIPMENT
VERSION 1.27
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copyright © 2010-2014 ARC
Contact information:
RFID Lab
Auburn University
Auburn, AL 36849
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TABLE OF CONTENTS
1. Test equipment ............................................................................................................. 3
1.1 Design and Description ............................................................................................. 3
1.1.1 Anechoic chamber ................................................................................................. 4
1.1.2 Test platform .......................................................................................................... 5
1.1.3 Antennas and cables ............................................................................................... 6
1.1.4 Measurement Unit ................................................................................................ 11
1.2 Equipment Calibration ............................................................................................ 14
Appendix A: Definitions ................................................................................................ 17
Appendix B: Equipment specification ......................................................................... 18
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ARC Benchmarking Equipment
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1. TEST EQUIPMENT
1.1 Design and Description
The test equipment was designed and developed to produce accurate, consistent,
and repeatable RF measurements. A layout of the test equipment is shown in Figure 1.
The major components of the setup are the anechoic chamber, the rotating test platform,
the antennas, the cables, and the measurement unit. The test equipment can measure
performance of RFID inlays for a variety of use cases.
Figure 1: High Level Layout of Test Equipment
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1.1.1 Anechoic chamber
The anechoic chamber was designed to eliminate reflections of electromagnetic
waves and provide an environment to accurately measure performance of RFID inlays.
The chamber is made of steel and sealed with copper lining to prevent any external
interference. All the internal surfaces of the chamber are lined with pyramidal radio
absorbent material which prevents RF waves from reflecting in the test environment. The
height of the pyramidal radio absorbent material used in the chamber is 0.3048 meters.
The antennas are mounted in the chamber using a frame made of a low dielectric material
commercially available as 80/20. The 80/20 is assembled using plastic nuts and bolts.
The fiber optic cable for the test platform passes through a wave guide on the wall of the
anechoic chamber. Antenna cables attach to connectors through the chamber wall. The
height adjustable test platform is located in the center of the chamber. All the other
components of the test equipment are kept outside the anechoic chamber.
The external length, width and height of the chamber are 4.5 meters, 4.5 meters
and 4.5 meters respectively. The chamber size is designed so that the tagged product will
be in far field of the test antennas for test products up to the size of a pallet. The
anechoic chamber is accessible through a steel door measuring 1.22 meters wide and 2.13
meters high. The interior of the door is lined with radio absorbent material. The edges of
the chamber and the door are lined with copper strips to prevent external interference
when the door is closed. An exterior view of the anechoic chamber is shown in Figure 2.
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Figure 2: Anechoic Chamber
1.1.2 Test platform
The anechoic chamber has a height-adjustable and rotating testing platform. The
platform has a low dielectric constant, and was chosen for its ability to support heavy test
products with minimum electromagnetic interference. The platform has a diameter of
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1.22 meters and thus has a surface area of 1.17 square meters. The height of the platform
can be adjusted from 0.6 meters to 1.2 meters above the floor of the chamber, and is
adjusted depending upon the dimensions of the test product.
To further minimize the interference of the turntable test platform, a smaller
platform made of 80/20 topped with Styrofoam blocks (dielectric constant of 1.05) is
used. This additional platform is placed on the larger platform when the test products are
of low weight and size.
The rotation of the test platform is performed using a stepper motor, which is
directly controlled by the measurement unit. As a result, the test platform can be rotated
360 degrees, in increments of 1 degree, with variable dynamically adjustable acceleration
and velocity.
1.1.3 Antennas and cables
Four linearly polarized patch antennas are used in the test setup. The antennas’
vertical linear polarizations have been rotated and mounted horizontally, so that they are
in parallel with the floor of the chamber. The antennas have an average gain of 8 dBi in
800 MHz to 1000 MHz frequency range. The antennas have VSWR less than 1.4 in the
800 MHz to 1000 MHz frequency range. The antennas are commercially available and
manufactured by HUBER+SUHNER. Detailed antenna parameters can be found in
Appendix B.
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The antennas are mounted at angles of 0 degrees, 30 degrees, 60 degrees and 90
degrees with respect to the floor of the chamber. The 0 degree, 30 degree, 60 degree and
90 degree antennas are named Antenna 1, Antenna2, Antenna 3 and Antenna 4,
respectively. Antenna 1 is mounted with its horizontal polarization plane parallel to the
floor of the anechoic chamber. The rest of the three antennas—Antenna 2, Antenna 3
and Antenna 4—are mounted in a similar way, with their horizontal polarization parallel
to the horizontal polarization of Antenna 1. The antenna configuration with respect to the
inlay and the test platform is shown in Figure 3. A photograph of the antennas and the
test platform is shown in Figure 4.
The antennas are directed at a single incident point. This incident point is where
the inlay to be tested is positioned, and can be seen in Figure 3. The antennas are
mounted and the test platform height is adjusted such that the incident point is exactly
above the center of the testing platform, which causes the center of the RFID inlay under
test to be at the incident point throughout the entirety of the test platform rotation. Inlays
are aligned to the antennas’ incident point using laser cross levels.
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Figure 3: Antenna Configuration
Figure 4: Antenna Configuration
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The distances of the antennas from the incident point are individually adjustable
between 0.5 meters and 2 meters. The distance from antenna to incident point is based on
two considerations: the distance must be short enough that the inlay can be read by the
antennas, and the inlay must also be in the electromagnetic far field of each of the test
antennas for all measurements. Once an optimal distance is determined, all the antennas
are mounted at the same distance from the incident point.
Orientation of the inlay on the test platform with respect to Antenna 4 is shown in
Figure 5. The 0 degree position is when the horizontal polarization of the inlay is parallel
to the polarization of antenna 4. The 90 degree position is when the horizontal
polarization of the inlay antenna is perpendicular to the polarization of antenna 4.
The antennas are monostatic; the forward and return communication happens
through the same antenna. The measurement unit can dynamically multiplex between
antennas if required during the measurement of an inlay.
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Polarization
of Antenna 4
Polarization
of Tag
0 degree 30 degree
60 degree 90 degree
Polarization
of Antenna 4
Polarization
of Tag
Polarization
of Antenna 4
Polarization
of Tag
Polarization
of Antenna 4
Polarization
of Tag
Figure 5: Table Position from Top of Chamber
Coaxial cables are used to connect the antennas to the test equipment. A set of
four cables connects the ports of the multiplexer to the through panel on the chamber
wall, and another set of four cables connects from the through panel inside of the
chamber wall to the antennas.
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1.1.4 Measurement Unit
The test equipment can generate, transmit, receive, and process UHF RF
communication. The configuration of the measurement unit is shown in Figure 6. The
transmitter of the measurement unit is connected to an amplifier to increase the maximum
power output offered by the measurement unit. The amplifier is dynamically controlled
by the measurement unit to achieve the desired level of power output. The return path
has two attenuators with a total attenuation of 9 dBm, which keeps the receiver within its
linear dynamic range. Both the transmitter and the receiver of the measurement unit are
connected to the multiplexer through a wideband circulator. The circulator has an
isolation of at least 20 dB between transmit and receive ports with a 50 ohm load. The
circulator is connected to a multiplexer, which interfaces with the measurement unit to
the four antennas. The multiplexer is also dynamically controlled by the measurement
unit to dynamically switch between antennas during the measurement process.
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Figure 6: Configuration of Measurement Unit
The measurement unit can operate in the 800 MHz to 1000 MHz frequency range,
and the frequency of operation can be dynamically controlled in increments of 1 MHz.
The accuracy of the transmitter’s oscillator is 10 ppm. The output power range of the
measurement unit is 0 dBm to 40 dBm, and can be dynamically controlled in increments
of 0.1 dBm. The absolute power accuracy is 1 dBm with an output power uniformity of
0.5 dBm.
The modulator in the measurement unit supports double-sideband amplitude shift
keying (DSB-ASK) modulation and phase-reverse amplitude shift keying (PR-ASK)
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modulation. The receiver has a sensitivity of -80 dBm with an absolute maximum input
power of 40 dBm.
The Select, Query, and Write commands can be used for measuring inlay
performance. A combination of Select and Query commands can be used to individually
test a specific inlay ID number in a population of multiple inlays present in the test
environment. As shown in Figure 7, the measurement unit sends a Select command with
the ID value of the inlay to measure. The Select command is followed by a Query
command for which the inlay should reply with a random number. The random number
response is used to validate the inlay response, and thus measure the inlay performance.
The write command is used for measurement by attempting to rewrite the first 16 bits of
the inlay ID with the value of 1010101010101010.
A graphical user interface is used to configure and control the test equipment.
The measurement unit also has a scripter-based interface where multiple tests can be
done automatically with all test parameters like frequency, power, antenna, and table
position controlled dynamically. The scripter and software is designed with a focus to
minimize user interaction.
The test equipment can measure the transmitted power, backscattered power and
relative backscatter phase. The equipment can also calculate and store parameters such
as theoretical read range based on the three measured parameters and the test setup
parameters. The equipment and the controller software were built by Voyantic Ltd.
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Figure 7: Communication Between Measurement Unit and RFID Inlay
1.2 Equipment Calibration
The transmitter of the test equipment was calibrated using a power meter with a
power trace in the entire operational frequency and power range. Both the I and Q
channels and their phase difference in the receiver were calibrated through the entire
frequency range by connecting the calibrated transmitter to the receiver.
A calibrated two-port network analyzer has been used to measure the S12
parameter of each antenna and cable combinations for the frequency range of 800 MHz to
1000 MHZ in increments of 1 MHz. The free-space loss in the chamber for the distance
between the antennas and the incident point is calculated using the Friis equation. The
loss of each antenna and cable combination combined with the corresponding free-space
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loss was used to calculate the total loss between the measurement unit and the incident
point.
The final measurement from the calibrated test equipment and calculated total
loss was validated and verified by measuring the performance of an externally verified
Calibration Inlay.
We measure a Quality Inlay at the beginning and end of measurement each day.
The Quality Inlay is measured on all four antennas and the consistency of the
measurement is verified to detect any unexpected change in the measurement system.
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LIST OF FIGURES
Figure 1: High Level Layout of Test Equipment ............................................................... 3
Figure 2: Anechoic Chamber ............................................................................................. 5
Figure 3: Antenna Configuration ....................................................................................... 8
Figure 4: Antenna Configuration ....................................................................................... 8
Figure 5: Table Position from Top of Chamber ............................................................... 10
Figure 6: Configuration of Measurement Unit ................................................................ 12
Figure 7: Communication Between Measurement Unit and RFID Inlay ........................ 14
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APPENDIX A: DEFINITIONS
Inlay – A specific combination of chipset and substrate antenna in the most finalized
format that would affect tagged product performance. Multiple conversions of the same
chipset and antenna combination do not constitute a unique ‘inlay’ unless the conversion
or application of the tag affects tagged product performance.
Tagged product – The final combination of inlay and product.
Calibration Inlay – The externally verified inlay that is retested and the observed values
are used to validate the calibration of the test equipment and calculated path loss in the
test setup.
Quality Inlay – An inlay that is measured during the beginning and end of each
measurement day to confirm the working condition of the test equipment.
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APPENDIX B: EQUIPMENT SPECIFICATION
Antenna Specification
Manufacturer Huber+Suhner
Model SPA 8090/75/8/0/V
Impedance 50 ohm
VSWR 1.4 (800 – 1000 MHz)
Polarization Linear
Gain 8.0 dBi
3dB beam width horizontal 75 degree
3 dB beam width vertical 70 degree
Downtilt 0 degree
Front to back ratio 20 dB
Max. power 75 W (CW) at 25 C
Measurement Unit Specification
Manufacturer Voyantic Ltd.
Model Tagformance Lite
Frequency range 800 – 1000 MHz
Frequency resolution 100 kHz
Frequency accuracy +- 10 ppm
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Output power 0 dBm to 40 dBm
Output power resolution +- 0.1 dBm
Output power absolute accuracy +- 1 dBm
Output power uniformity +- 0.5 dBm
Output impedance 50 ohm
Modulation modes DSB-ASK, PR-ASK (Tari= 25 µs)
Modulation waveform resolution 16-bit, non-linear
Modulation waveform sample rate 1000 kS/s
Receiver usable linear dynamic range -80 dBm to 10 dBm
Receiver absolute maximum input power 30 dBm
Receiver sensitivity -80 dBm
Backscattered waveform resolution 16-bit
Backscattered waveform sample rate 1000 kS/s
Input impedance 50 ohm
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